Natural allelic variation confers high resistance to sweet potato weevils in sweet potato

Sweet potato (Ipomoea batatas L.) is a major root crop worldwide. Sweet potato weevils (SPWs) pose one of the most significant challenges to sweet potato production in tropical and subtropical regions, causing deleterious economic and environmental effects. Characterizing the mechanisms underlying natural resistance to SPWs is therefore crucial; however, the genetic basis of host SPW resistance (SPWR) remains unclear. Here we obtained two sweet potato germplasm with high SPWR and, by map-based cloning, revealed two major SPW-resistant genes-SPWR1 and SPWR2-that are important regulators of natural defence against SPWs. The SPW-induced WRKY transcriptional factor SPWR1 directly activates the expression of SPWR2, and SPWR2, the conserved dehydroquinate synthase, promotes the accumulation of quinate derivative metabolites that confer SPWR in sweet potato. Generally, our results provide new insights into the molecular mechanism underlying sweet potato-SPW interactions and will aid future efforts to achieve eco-friendly SPW management. Sweet potato weevils (SPWs) pose one of the most significant challenges to sweet potato production. This study identifies two major SPW-resistant genes, SPWR1/2, and provides new insights into the mechanism of sweet potato defence against SPWs.

Automated summary

Sweet potato weevils (SPWs) are a major threat to sweet potato production. This study identifies two major SPW-resistant genes, SPWR1/2, and provides new insights into the mechanism of sweet potato defence against SPWs.